DE112009001176T5 - Floating rotary kiln - Google Patents

Abstract

Rotary kiln comprising:
an insulated heating chamber;
wherein the insulated heating chamber has a product discharge outlet and a process tube inlet;
a heating element operatively configured to selectively heat the heating chamber;
a generally horizontally extending process tube supported for rotation relative to the heating chamber;
the process tube having a first portion disposed generally outside the heating chamber and a protruding second portion extending into the heating chamber from the first portion and terminating at an introduction discharge end inside the heating chamber;
an introduction mechanism constructed and arranged to introduce product into the process tube; and
a bearing assembly which acts between a support member and the first portion of the process tube and is constructed and arranged to support the process tube and transmit torque to the process tube.

Description

Cross-reference to related applications

The present application claims the benefit of US Provisional Patent Application No. 62 / 127,423, filed May 13, 2008. The entire contents of this application are hereby incorporated by reference.

Technical area

The present invention relates to rotary kilns for high temperature treatment of various materials, and more particularly to a rotary kiln.

Technical background

Rotary kilns with direct heating are widely used for physical and chemical conversion of both solids and powders. U.S. Patent No. 6,042,370 discloses an oven having a graphite tube inside an oxygen-free chamber with graphite heating elements that can heat to temperatures of 2800 ° C. It is known that graphite can be used as one of the building materials for such furnaces. It is also known that ovens operating at extreme temperatures often require treatment of the processed material in an inert atmosphere, such as a non-oxidizing atmosphere, to avoid undesirable reactions. Furthermore, when used as part of the furnace, graphite may also react with oxygen and air at extremely high temperatures. Therefore, it is known to provide an inert atmosphere which envelops furnace furnaces of graphite as well as the processed material.

Disclosure of the invention

The present invention provides a rotary kiln with corresponding parts, portions, or surfaces of the disclosed embodiment, which are numbered in parenthesis and are for purposes of illustration and not of limitation. 1 ), which has an insulated heating chamber ( 4 ) having a product ejection outlet ( 21 ) and a process tube inlet ( 39 ), a heating element ( 14 ) operatively configured to selectively heat the heating chamber, a generally horizontally extending process tube (US Pat. 2 ) which is rotatably mounted relative to the heating chamber and a first section ( 36 ) disposed generally outside the heating chamber and a projecting second portion (FIG. 37 ) extending from the first portion into the heating chamber and at an inlet discharge end (FIG. 38 ) inside the heating chamber ends, an introduction mechanism ( 40 ), which is constructed and arranged to introduce product into the process tube, and a bearing assembly which is sandwiched between a support frame (Fig. 34 ) and the first portion of the process tube and is arranged and arranged to support the process tube and transmit torque to the process tube.

The heating chamber may have an outer casing ( 10 ), a thermally conductive muffle ( 15 ) as well as an insulating layer ( 11 ) between the outer shell and the muffle. The heating chamber can be a gas inlet ( 16 ) and a gas outlet ( 20 ) operatively configured to maintain a selected gas atmosphere around the process tube in the heating chamber. The product ejection outlet may include an ejection shaft ( 22 ) and an ejection heating element ( 25 ) operatively configured to selectively heat the ejection shaft. The heating element may be operatively configured to selectively heat the heating chamber to at least 1200 ° C, and the heating element may be operatively configured to selectively heat the heating chamber to about 2600 ° C. The heating element may be a graphite resistance heating element or the heating element may be an induction coil ( 30 ) and a graphite susceptor ( 31 ). The process tube can be made of graphite or quartz. The process tube can be a lining ( 3 ), and the lining may be made of quartz or ceramic. The process tube may include two or more tube sections. The introduction mechanism comprises an introduction device ( 7 ) with an inlet tube ( 6 ), which extends into the process tube. The inlet tube may extend through the first portion of the process tube and at an inlet ejection end (FIG. 42 ) end inside the heating chamber. The oven may further comprise an insulating cutting disc ( 13 ) between the inlet tube and the process tube. The inlet tube can be a gas connection ( 17 ) operably configured to selectively effect a direct current or countercurrent flow of gas through the process tube. The bearing assembly may include a drive motor ( 35 ), an inner flexible ring ( 26 ) extending around the first portion of the process tube, an outer cylindrical member ( 5 ), which is connected to the ring and the drive motor, and a pair of rollers ( 9 ) supporting the cylindrical member, the cylindrical member counterbalancing the projecting second portion of the process tube. The process tube may be inclined from the discharge discharge end toward the first portion.

In a further aspect, the invention provides a rotary kiln having a heating zone ( 48 ), the an insulated heating chamber having a product ejection outlet and a process tube inlet, a heating element operatively configured to selectively heat the heating zone, a generally horizontally extending process tube supported for rotation relative to the heating chamber, and an inlet Entry end ( 43 ) as well as a product discharge end ( 38 ), an introduction mechanism constructed and arranged to introduce product into the process tube, and a bearing assembly which acts between a support member and the process tube and is constructed and arranged to support the process tube and to apply torque to the process tube Process tube transmits, and wherein the process tube and the storage assembly are constructed and arranged so that the product discharge end is within the heating zone.

In another aspect, the invention provides a rotary kiln having an insulated heating chamber having a product discharge outlet and a process tube inlet, a heating element operably configured to selectively heat the heating chamber, a generally horizontally extending process tube mounted for rotation relative to the heating chamber and having an introduction-entry end portion and a product discharge end portion, and an introduction mechanism constructed and arranged to introduce product into the process tube, the introduction mechanism comprising an introduction device communicating with an inlet tube extending through the process tube inlet of the heating chamber, the inlet tube comprising an end portion extending into the heating chamber and terminating in the interior of the heating chamber, the inlet tube having a thermal barrier (US Pat. 27 ) at the end portion, and a bearing assembly which acts between a support member and the process tube and is constructed and arranged to support the process tube and transmit torque to the process tube.

One object is to provide an improved rotary kiln which provides the materials to be processed without premature melting.

Another object is to provide an improved rotary kiln which ejects the processed materials without premature solidification.

Another object is to provide an improved rotary kiln which processes materials at high temperatures without the material adhering to the processing equipment.

Another object is to provide an improved rotary kiln in which material flow is not hindered by undesirable material deposition.

These and other objects and advantages will become apparent from the foregoing and the following further description, drawings and claims.

Brief description of the drawings

1 1 is a sectional view of a first embodiment of the rotary kiln of the present invention.

2 is a sectional view of an alternative embodiment of the in 1 shown rotary kiln.

3 is a partial cross vertical sectional view of the in 1 shown embodiment generally along the line 3-3 in 1 ,

4 is a partial longitudinal vertical sectional view of the in 1 shown embodiment generally along the line 4-4 in 3 ,

5 is a partial sectional view of a third embodiment of the in 1 shown rotary kiln.

6 is a partial sectional view of a fourth embodiment of the in 1 shown rotary kiln.

Description of preferred embodiments

First of all, it should be understood that throughout the several figures, like reference numbers designate the same structural elements, portions and surfaces throughout, as these elements, portions or surfaces are further described or illustrated throughout the specification, the integral part of which is this detailed description. The drawings are to be read in conjunction with the specification (eg, hatching, placement of parts, proportion, degrees, etc.) and are to be considered as part of the overall description of the present invention. The terms "horizontal", "vertical", "left", "right", "top" and "bottom" and adjectival and adverbial derivatives thereof (eg, "in the horizontal direction", "to the right", "upwards , Etc.) as used in the following description refer to the orientation of the illustrated structure when the particular drawing faces the reader. Likewise, the terms "inward" and "outward" generally refer to each other the orientation of a surface relative to the axis of its extension, or axis of rotation.

The present invention provides, as with reference to the drawings and in particular 1 can be seen, an improved rotary kiln, wherein a first embodiment of the same generally with 1 is marked. oven 1 As shown, generally includes an insulated heating chamber 4 , a heating element 14 functionally configured to selectively heat the heating chamber, a horizontally extending graphite process tube 2 extending along the axis xx and supported for rotation about axis xx, an introduction mechanism 41 which is built and set up to be a product in a process tube 2 initiates, as well as a storage assembly 41 between a support frame 34 and process tube 2 acts and process tube 2 carries and torque on process tube 2 transfers.

oven 1 is how in 1 shown in a heating section 48 and a drive or entry section 47 divided. heating section 48 from oven 1 includes a heating chamber 4 inside an insulating sheath 11 , in turn, in metal sheath 10 which may be made of a suitable heat-resistant material such as stainless steel. In the preferred embodiment, insulation 11 a high temperature insulation such as molded carbon fiber or other suitable fibrous insulation. heating chamber 4 contains one or more conventional heating elements 14 that is / are set up to be a heating chamber 4 selectively heated / heated. In the in 1 shown embodiment are heating elements 14 Graphite resistance heating elements. However, it is envisaged that other heating methods will be used. For example, as in 2 shown graphite tube 2 using conventional induction coils 30 and the graphite susceptor 31 be heated inductively. heating chamber 4 also contains a highly conductive graphite muffle 15 covering the area where material from process tube 2 is ejected from the heating elements 14 separates. This separation of heating elements 14 and the process area allows for heating elements 14 be rinsed with clean, non-oxidizing gas.

The thermally insulated heating chamber 4 surrounds the section of tube 2 heated with at least one control zone and at least one element per control zone. Although, however, oven 1 is shown as having a single heating zone, can heating chamber 4 be divided into several temperature zones, which are separated by Isoliersperren to allow greater temperature resolution. So can heating elements 14 be energized and positioned as desired to provide a constant temperature throughout the heating zone or to provide multiple thermal cycling temperature zones.

heating chamber 4 contains a number of ports. Material that is processed enters the bottom of heating chamber 4 over ejection arrangement 21 out. ejection assembly 21 includes a channel heating chamber 24 inside a duct insulation enclosure 46 , Channel heaters 25 heat channel heating chamber 24 , ejection channel 22 passes through channel heating chamber 25 through and is heated separately. A lining 23 can in discharge channel 22 be present to facilitate movement of processed material. Accordingly, ejection channel 22 heated separately to prevent molten material from the process tube 2 exits, cools prematurely and at discharge channel 22 or his lining 23 liable. ejection channel 22 may feed a solidifying unit or other conventional catching device.

process tube 2 extends over process tube inlet 39 in heating chamber 4 into it. process tube 2 is generally a cylindrical element of graphite or quartz extending along the axis xx, and is arranged to rotate about axis xx. process tube 2 extends from the entry or drive section 47 from oven 1 in heating chamber 4 of the heating section 38 from oven 1 into it. Although it is shown as extending horizontally, it is a process tube 2 Under normal operating conditions relative to the horizontal inclined to the movement of materials through process tube 2 through support. Furthermore, process tube 2 although it is shown as being made up of a single tubular unit, it consists of two or more interconnected tube sections, depending on various considerations, such as the required overall length and the specific requirements for each section of the tube. Furthermore, the materials used to form the tube sections may vary depending on their position in the oven, wherein the sections of tube 2 , the insulating plugs 13 are upstream, rather metal than graphite existing sections are. In the preferred embodiment, tube contains 2 an inner lining 3 , In the preferred embodiment is lining 3 a quartz tube. However, it is contemplated that this inner or second tube may be made of graphite or ceramic, such as silicon carbide, alumina or mullite, depending on aspects such as the materials being processed. lining 3 may be a second element of sacrificial graphite.

introducing mechanism 40 is how in 1 shown, available to process tube 2 Supply material or product. In the preferred embodiment, introduction mechanism 40 an inlet funnel 12 , an introduction device 7 and an introduction tube 6 at an inlet discharge end 42 inside of process tube 2 ends. By means of process tube 2 material to be treated enters funnel 12 a, from where it then through inlet device 7 in inlet tube 6 is delivered. The material then passes through the remaining section of process tube 2 , In this embodiment, introducing means 7 an introduction device 45 of the screw type, and introduction tube 6 contains a lining 44 , inducer 7 However, it may be a vibratory or compressed air introduction device, and it may, as in 5 and 6 shown a flexible bellows 28 between metal sheath 10 and inlet tube 6 be arranged so that movement of inlet tube 6 , such as vibration, is not hindered and there is sufficient gasket to trap gas. Furthermore, a lock 29 in process tube 2 or in lining 3 from process tube 2 be present to prevent the backflow of introduced material. Other types of introducers may also be used. For example, a reciprocating blade type injector may be employed in which paddled material is introduced into the hot zone in groups of blades.

The length of the inlet tube 6 can vary as desired. For example, in the 6 embodiment shown inlet tube 6 only in the first section 36 from tube 2 into and ends well before section 37 from process tube 2 and inlet 39 in heating chamber 4 , In this embodiment, no insulating separator 13 used. As an alternative, the inlet tube may 6 , as in 1 and 2 shown in sections 37 from process tube 2 extend into and immediately beyond the inlet 39 from heating chamber 4 end up. In this embodiment, an insulating separator 13 between the outer cylindrical surface of inlet tube 6 and the inner cylindrical surface of lining 6 in process tube 2 available. In another, in 5 shown embodiment extends inlet tube 6 further than in the 1 and 2 shown embodiment in the heating chamber 4 into it. In this embodiment, an inlet tube thermal barrier is 27 for the section of inlet tube 6 available, which is about inlet 39 out in heating chamber 4 extends into it to limit the heating of the material, via the inlet tube 6 is initiated. Thus, in this embodiment, material can be directly into the heated part of the process tube 2 be initiated.

process tube 2 As shown, it is carried over its entrance end and has a protruding portion 37 up, free on inlet 39 in heating chamber 4 extends into it. So has heating tube 2 a first section 36 which is generally outside of heating chamber 4 is arranged, as well as a projecting section 37 up, extending from the first section via inlet 39 in heating chamber 4 extends into and at an inlet discharge end 38 inside of heating chamber 4 ends. This brings a number of unexpected benefits. Through the projecting tube 2 is suitable oven 1 to partially melt material in a continuous feed system without premature melting. Furthermore, since the material is above the inlet discharge end 38 from tube 2 is discharged into the hot zone of the furnace, the material ejected without premature solidification. Through inlet tube 6 causes the return of heat from the heating chamber 4 no melting and thus sticking or sticking of material being processed on the walls of process tube 2 , Furthermore, by ejecting over the projecting section 37 in heating chamber 4 reduces the likelihood that material will adhere to each other or to the tube walls or downstream surfaces, thereby preventing material flow.

process tube 2 will, as in 3 and 4 shown in their projecting orientation with storage arrangement 41 worn and turned. In this embodiment, storage arrangement 41 an engine 35 that with a sprocket 50 with drive chain arrangement 8th connected is. Sprocket 50 is in turn with a metal hoop 5a connected. The tires 5 are with process tube 2 each with flexible rings 26 connected, the friction adhesion to the outer surface of the first section 36 from process tube 2 maintain and at the same time any thermal expansion differences between the process tube 2 and ring 26 compensate. The flexibility of ring 26 is due to several springs 32 ensures that between sections of the cylindrical ring 26 Act. In this embodiment, ring 26 through a connecting rod 33 with tires 5 connected. So turn drive motor 35 and arrangement 8th Sprocket 50 and with it tires 5a , Rotation of tires 5a about axis xx causes rotation of ring 26 and turn rotation of process tube 2 around axis xx.

Two rollers 9 made of steel, with frame 35 are connected, wear, as in 3 shown, each the metal tire 5 , tires 5a who is closest to initiation device 7 is sufficiently loaded to the weight of the overhanging or projecting portion 37 from tube 2 counteract. The weight of tires 5a Not only enough to the projecting section 37 from process tube 2 but also any counteracting additional weight by lining 3 or other devices on process tube 2 arises. The roles 9 , the tires 5b are at the pivot point between the first section 36 and the projecting portion 37 from process tube 2 positioned. The weight of the tires 5 and associated connector is such that the focus of process tube 2 along axis xx between the tires 5a and 5b located. So tilts process tube 2 not down from the roles. A positioning roller can also be attached to drive tires 5a be arranged to contribute to the position of tube 2a along axis xx in the horizontal direction. Although in this embodiment, a storage arrangement 41 has been described with two tires, it is envisaged that other storage or drive arrangements can be used.

When operating at high temperatures, it is often preferable to have a non-oxidizing atmosphere, such as a nitrogen or an argon gas atmosphere, in the heating chamber 4 and process tube 2 maintained. In this embodiment is entrance 43 from process tube 2 enclosed in or surrounded by a chamber that excludes air, dust and light. heating chamber 4 , this inlet chamber and the ejection arrangement 21 form a cladding, with which the selected atmosphere around process tube 2 around and in its interior is maintained. The interior atmosphere of process tube 2 can be controlled by passing a non-oxidizing gas such as nitrogen through it. If a direct current of gas is desired, gas will be via port 17 from inlet tube 6 provided and occurs via process opening 20 from heating chamber 4 out. If countercurrent is desired, the direction of the current can be reversed. There may also be a countercurrent of non-oxidizing gas in the discharge channel 22 be generated. Furthermore, a non-oxidizing atmosphere in heating chamber 4 be generated by an overpressure of gas over heating chamber 4 using gas permeation 16 in heating chamber 4 is maintained in it. Furthermore, a desired atmosphere in introduction mechanism 41 using inlet 18 in funnels 12 be created. Likewise, a desired atmosphere in entrance or drive section 47 via a drive area gas connection 19 be created. This allows many changing atmospheres and alternating direct currents in the oven 1 be used.

The hanging graphite rotary kiln 1 can be used to process various types of introducing materials, including particulate material. For example, oven 1 be used to process silicon particulate material, wherein the silicon particulate material inside the quartz-lined process tube 2 melts and as a liquid over ejection assembly 21 exit. oven 1 is generally suitable for the treatment of particulate material that melts at temperatures up to 2600 ° C. The preferred temperature range of oven 1 ranges from 1200 ° C-2200 ° C. For silicon processing, the preferred temperature is about 1500 ° C, and the material may be melted directly into the heated and protruding section 37 from process tube 2 be initiated.

The present invention provides that many changes and modifications are made. Therefore, while the presently preferred form of the improved oven has been illustrated and described and a number of alternatives have been explained, it will be apparent to those skilled in the art that various additional changes and modifications may be made without departing from the spirit of the invention as defined by the following claims are defined and delimited.

Summary

Floating rotary kiln

A rotary kiln ( 1 ) comprises an insulated heating chamber ( 4 ), which has a product discharge outlet ( 21 ) and a process tube inlet ( 39 ), a heating element ( 14 ) operatively configured to selectively heat the heating chamber, a generally horizontally extending process tube (US Pat. 2 ) which is rotatably mounted relative to the heating chamber, and a first portion ( 36 ), which is generally located outside the heating chamber, and a projecting second section ( 37 ) extending from the first portion into the heating chamber and at an inlet discharge end (FIG. 38 ) inside the heating chamber ends, an introduction mechanism ( 40 ), which is constructed and arranged to introduce product into the process tube, and a bearing assembly which is sandwiched between a support frame (Fig. 34 ) and the first portion of the process tube and is arranged and arranged to support the process tube and transmit torque to the process tube.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6042370 [0003]

Claims (39)

Rotary kiln comprising: an insulated heating chamber; wherein the insulated heating chamber has a product discharge outlet and a process tube inlet; a heating element operatively configured to selectively heat the heating chamber; a generally horizontally extending process tube supported for rotation relative to the heating chamber; the process tube having a first portion disposed generally outside the heating chamber and a protruding second portion extending into the heating chamber from the first portion and terminating at an introduction discharge end inside the heating chamber; an introduction mechanism constructed and arranged to introduce product into the process tube; and a bearing assembly which acts between a support member and the first portion of the process tube and is constructed and arranged to support the process tube and transmit torque to the process tube. The rotary kiln of claim 1, wherein the heating chamber comprises: an outer shell; a thermally conductive muffle; and an insulating layer between the outer sheath and the muffle The rotary kiln of claim 1, wherein the heating chamber includes a gas inlet and a gas outlet that are operatively configured to maintain a selected gas atmosphere around the process tube in the heating chamber. The rotary kiln of claim 1, wherein the product discharge outlet comprises a discharge channel and an exhaust heating element, which is operatively configured to selectively heat the discharge channel. The rotary kiln of claim 1, wherein the heating element is operatively configured to selectively heat the heating chamber to at least 1200 ° C. The rotary kiln of claim 1, wherein the heating element is operatively configured to selectively heat the heating chamber to about 2600 ° C. Rotary kiln according to claim 1, wherein the heating element is a graphite resistance heating element. The rotary kiln of claim 1, wherein the heating element comprises induction coils and a graphite susceptor. Rotary kiln according to claim 1, wherein the process tube consists of graphite or quartz. The rotary kiln of claim 1, wherein the process tube comprises a liner. Rotary kiln according to claim 10, wherein the lining consists of quartz or ceramic. The rotary kiln of claim 10, wherein the process tube comprises two or more tube sections. A rotary kiln according to claim 1, wherein the introduction mechanism comprises an introduction means communicating with an introduction tube extending into the process tube. A rotary kiln according to claim 13, wherein the introduction tube extends through the first portion of the process tube and terminates at an introduction-discharge end inside the heating chamber. A rotary kiln according to claim 14, further comprising an insulating separator between the introduction tube and the process tube. The rotary kiln of claim 13, wherein the inlet tube comprises a gas port that is operatively configured to selectively provide a direct current or a countercurrent flow of gas through the process tube. Rotary kiln according to claim 1, wherein the storage arrangement comprises: a drive motor; an inner flexible ring extending around the first portion of the process tube; an outer cylindrical member connected to the ring and the drive motor; and a pair of rollers supporting the cylindrical member; wherein the cylindrical member forms a counterweight to the projecting second portion of the process tube. The rotary kiln of claim 1, wherein the process tube is inclined from the discharge end to the first portion. A rotary kiln comprising: a heating zone comprising an insulated heating chamber having a product discharge outlet and a process tube inlet; a heating element operatively configured to selectively heat the heating chamber; a generally horizontally extending process tube supported for rotation relative to the heating chamber and having an inlet entry end and a product introduction and discharge end; an introduction mechanism constructed and arranged to introduce product into the process tube; a bearing assembly that acts between a support member and the process tube and is constructed and arranged to support the process tube and transmit torque to the process tube; and wherein the process tube and the storage assembly are constructed and arranged such that the product introduction discharge end is within the heating zone. The rotary kiln of claim 19, wherein the heating zone comprises: an outer shell; a thermally conductive muffle; and an insulating layer between the outer sheath and the muffle The rotary kiln of claim 19, wherein the heating zone includes a gas inlet and a gas outlet that are operatively configured to maintain a selected gas atmosphere around the process tube in the heating zone. The rotary kiln of claim 19, wherein the product discharge outlet comprises a discharge channel and an exhaust heating element operatively configured to selectively heat the discharge channel. The rotary kiln of claim 19, wherein the heating element is operatively configured to selectively heat the heating zone to at least 1200 ° C. The rotary kiln of claim 19, wherein the heating element is operatively configured to selectively heat the heating zone to about 2600 ° C. A rotary kiln according to claim 19, wherein the heating element is a graphite resistance heating element. The rotary kiln of claim 19, wherein the heating element comprises induction coils and a graphite susceptor. A rotary kiln according to claim 19, wherein the process tube is made of graphite or quartz. The rotary kiln of claim 19, wherein the process tube comprises a liner. Rotary kiln according to claim 28, wherein the lining consists of quartz or ceramic. The rotary kiln of claim 19, wherein the process tube comprises two or more tube sections. A rotary kiln according to claim 19, wherein the introduction mechanism comprises an introduction means communicating with an introduction tube extending into the process tube. A rotary kiln according to claim 31, wherein the introduction tube extends through the first portion of the process tube and terminates at an introduction-discharge end inside the heating zone. A rotary kiln according to claim 32, further comprising an insulating separator between the introduction tube and the process tube. The rotary kiln of claim 19, wherein the processing inlet end of the process tube includes a gas port operably configured to selectively provide a direct current or a countercurrent flow of gas through the process tube. A rotary kiln according to claim 19, wherein the storage arrangement comprises: a drive motor; an inner flexible ring extending around the process tube; an outer cylindrical member connected to the ring and the drive motor; and a pair of rollers carrying the cylindrical member. A rotary kiln according to claim 19, wherein the process tube is inclined from the discharge discharge end to the first portion. A rotary kiln comprising: an insulated heating chamber; wherein the insulated heating chamber has a product discharge outlet and a process tube inlet; a heating element operatively configured to selectively heat the heating chamber; a generally horizontally extending process tube supported for rotation relative to the heating chamber and having an inlet entry end portion and a product discharge end portion; an introduction mechanism constructed and arranged to introduce product into the process tube; wherein the introduction mechanism comprises an introduction means communicating with the introduction tube extending through the process tube inlet of the heating chamber; the introduction tube includes an end portion that extends into the heating chamber and terminates inside the heating chamber; wherein the introduction tube has a thermal barrier at the end portion; and a bearing arrangement acting between a support member and the first portion of the process tube and constructed and arranged such that she carries the process tube and transmits torque to the process tube. A rotary kiln according to claim 37, further comprising an insulating separator between the introduction tube and the process tube. A rotary kiln according to claim 37, wherein the product discharge end portion of the process tube is protruded.

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